Television relay system



Feb- 24, 1959 J; H. HAMMOND, JR

TELEVISION RELAY SYSTEM 4 Sheets-Sheet l Filed March 9, 1955 Na/ffm .5,055.0

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TELEV Feb. 24, 1959 ISION RELAY SYSTEM 4 Sheets-Sheet 2 Filed March 9, 1955 z/D/o 2 /f/@A c Won/Az IP55@ A. M. /Pfcf/ VE@ 43 2 /W f@ w, M w A p @l A TTO/SNfy Feb. 24, 1959 2,875,436

J. H. HAMMOND, JR

TELEVISION RELAY SYSTEM Filed Maron 9, 1955 4 sheets-sheet 5 Lf. F.

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TELEV Feb. 24, 1959 ISION RELAY SYSTEM 4 Sheets-Sheet 4 Filed March 9, 1955 y 2,875,436 y p, TELEVISION RELAY SYSTEM ohn Hays Hammond, Jr., Gloucester, Mass. Application March 9, 1951s, serial No. 493,260

" s Claims. (ci. 343-1202) This invention relates to television andinore particu.- larly to television relay systems for transmitting televisiontype signals by radioover long distances. l @This application is a continuation in part of' my copending application Ser. No. 414,055, tiled March 4, 19,54, for Television Relay System.

"An `object of this invention is to provide a system by which televsionprograms can be sent from a master station simultaneously to any number of distant broadcasting stations by a radio carrier wave instead of by ,transmission over microwave links, coaxial cables, orby the physical transportation of recordings on film, tape, or wire. i p The' invention provides a method-of sending programs to the various stations of a network which is much less expensive than by the use Vof micro-wave-link systems or cables, and the interruptions caused by equipment failure, so common with microwave links, is eliminated. The invention also provides means for relaying television programs over bodies of water and mountainous terrain where the installation of microwave links or cables would be difcult `or impossible. p

Other objects and advantages will be apparent as the nature of the invention is more fully disclosed. p

The video` and synchronization signals of standard television require aband width of from 30 cycles per secondto between 3 and 4 megacycles per second. Such a wide-band modulation of a radio carrier wave necessitates thatthe carrier-wave frequency be sufficiently high so that the fractional radio-frequency band Width is limited to practical values, generally less than percent. As a consequence, the carrier-wave frequencies of standard television are restricted bytheFederal Communication Commission to theradio spectrum above 50 megacycles per second. Unfortunately, however, these radio waves are `in; general not reflected by the ionosphere and hence are transmitted only short distances seldom exceeding lineof-sight ranges. l

jIt is.` well known that radio waves having frequencies in the l() to` 30 megacycle regionare strongly reflected by the Iionosphere and consequentlyfare reliably transmitted over long distancesfeveu thousands `of miles. l 1

Television programs could be transmittedl overv carrier waves in the `10 to 30 rnegacycle range only if the modulatf ing-frequency band width is compressed so as to limit the fractional band width of the` radio emission to practical values. If the same fractional band width is permitted at a lower carrier-wave frequency as in standard `television the reduction of the modulation spectrum would `have to be in the same ratio as thereduction in carrier-wave frequency, and this reduction factor might be no more than twoor three to elfect a very considerable increase in United States Patent O l 2,875,436 `Patented Feb. 24, 19,59

spectum must be compressed also to one half its original width, and two hours would be required to transmit a one hour program. In order, therefore, `to maintain aboutthe same rate of flow of information as relayed from the master station to the distance local broadcasting stations as for the standard television, there must be provided means for transmitting simultaneously two or more relayed programs. If the factor of compression is two, for example, an hours program could be relayed in one hour by dividing the record into two parts and sending them simultaneously by multiplex transmission. lThe same rate of relaying programs could also be accomplished by sending two different programs simultaneously by the multiplex transmission of the present invention. p

This invention provides means not only for compressing the modulation spectrum, but also it provides cooperating means for multiple` transmissionof the relayed programs so as to maintain approximately the same rate of Iow of program material as for the standard television stations connected by microwave links or coaxial cables.

The complete procedure in the practice of this invention is explained in terms of steps which Vare briefly described below. In the first step the video, synchronization, and audio signals, as furnished by the camera when viewing a live program, are recorded on a suitable medium such as a magnetic tape driven at a suitable speed, which will be referred to as normal speed In the second step of the process the video and synchronization signals are taken from the tape or other medium when driven at a fraction of normal speed, and used to modulate a multiplexA transmitter having a carrier frequency lower than l would be used for direct television broadcast. The other `Compressing the modulation` spectrum afactor.

necessarily increases the time required for transmitting a program` bythe same factor.` For example, if the carrier waveis reduced from` 50 to 25 megacycles the modulation master station; f

channels of the multiplex transmitter will simultaneously transmit vsignals derived from one or more additional transcribers having tapes or other media driven at the fractional speed. `Intherthird` -step the radio carrier is received at a distant station and the two or more compressed signals are separately derived from the multiplex transmission and recorded on tapes or other media on two or more transcribers, the tapes or other media being driven at fractional speed. In the final and fourth step of the processlthe program signals recovered from one of the tapes or other media while driven at` normal speed, are used to modulate in the usual way` a television transmitter for local broadcast. The signals derived from. the other tapes or media are used successively to modulate the transmitter.

The audio signals which were recorded and compressed `in step one would be transmitted to the distant station by telephone wires orY by other radio channels,`

master `tape to any number of distant television stations for broadcasting to the local area served by each station. Thus a large area canbe provided with television programs from one master station without the. use of high p cost `connections between stations such as coaxialcables or `microwave radio links.

The invention may be more fully explained by refer-A of recording the video and audio signals on tapexatfthe illustrating the rst step illustrating the process bf" obtaining the compressedlvideo and audio signals from a movingpicture film. Y Figure 4 is a block diagram illustratingthe step of receiving the program at the remote station'and recording the two halves of the Yprogram or two separate programs on magnetic tape at reduced speed; f

f Figure S is a block diagram illustrating the process of 'broadcasting the program derived from the tape at the remote station.

Figures 6a and 6b are vector diagrams showingamplitude and phasel modulation; l' l Figure 7 is a block diagram showing one kind of 'multiplex transmitter embodying the present invention; and

Figure 8 is a block diagram of one form of a receiver for multiplex transmission embodying the present invention.

In the following description parts will be identiiied by specific names for convenience, but they are intended tol be generic n their application to similar parts.

The iirst step in` the practice of the invention is illustrated in Figure l. A scene is converted into video isignals by a television camera 2 of standard type. These signals, together with synchronizing pulses produced in camera 2, are conducted by line 7 to a video amplifier 8, and then by line 9 to a recording head or heads 10 of a magentic tape 'recorder 11. Microphone 3 provides audio signals whichv are amplified by audio ampliiier`12. The amplied audio signals are conducted by line 1 3 to the recording head 14 of recorder 11. All of these signals are-recorded on a magnetic tape 15 operating at a normal speed for such recording. For black and white video signals, one ltrack may be used for the video, one track for the synchronizing signal,'and one track. for the sound. vIf color Video signals are recorded at least two more tracks are required.` Any known technique of recording Video signals on tape may be used.

If, in the process described above, the video and'synchronizing signals are recorded on separate tracks, signal-separation circuits -would be included in block 8, and two lines in place of the one line 9 would conduct the two signals to two recording heads instead of the single head asshown in Figure l.- In subsequent iigures, as in Figure l, the video andl synchronizing signals are assumed combined and recorded in asingletrack but they r mayv be recorded in separate tracks as stated in which-case the same additional recording or transcribing head and separation or vcombining circuits would be added 'without aiecting the basic steps involved in thisl invention. e e f The second step in the practice of this invention is il- '4 l recorded on moving-picture film instead of beingaiive program. The moving-'picture iilm 30 is fed from reel 31 to reel 32 at the fraction of normal speed used in driving the tapes of Figure 2. A light 33 illuminates the picture on the iilm, an image of which is cast on the iconoscope or equivalent photo-electric transcriber contained in camera 34. The v idep and synchronizing signals are then supplied over line' 35 to post 28 of Figure 2 or to an equivalent multiplex transmitter. The audio signal, taken from sound head 36, is fed through line 37 to the same transmitting means a's--forthe signals over line 27 of Figure 2. A duplicate ofthe'equipment in Figure 3 could also replace transcriber 21, or a live program could be sent by transcriber 21 along with a nlm-recorded program.

Steps l and 2 or the variation of steps l and 2 shown in Figure 3 take place at the master relay station. The third step. in the practice of this invention is sh own in Figure `4`an`d takes place at one of the-distantreceiving statins. The doubly modulated carrierwwave,.,o/f say 2 5 megacycles, is received by antennav 40,' and the two modulation signals separately derived-'by the two receivers 414 and 42, receiver 41` being only responsive to amplitude modulation and receiver 42 being only responsivejto'phase modulation. The operation of these two receivers will be described later.

The video and synchronizing`signals,`derived vfrom t transcriber 420 and sent by amplitude modulation, are

reproduced by receiver 41 and fed over line 43 toA recording head 44 of recorder 46, and recorded on ta`p'e.45I driven at fractional speed. Similarly and simultanedusly the video and synchronizing signals derived `from recorder 21 and sent by phase modulation, are reproduced by receiver42 and fed by line 47 to recording head 48.A and recorded'by head 48 on tape 49 of recorder 50 driven Aat fractional speed. Thus tw'o programs or two halvesof the same program are simultaneously recorded. ,The corresponding audio signals transmitted by telephone line or radio are conducted by lines 51 and 52, and recorded on the corresponding tapes by s'oundrecording heads 53 and 54, respectively. j

The fourth and final step .in the practice of this invention is illustrated in Figure 5. The tape61, which may lustrated in Figure 2. Two transcribers 20 andi-'21 have tapes or "othermediafon'which have been recorded by the method of' Figure l either thetwo halves of'a program or two separate programsf The 'tapesor other mediafaredriven at a fraction-of normal speed and one ofrthe two video and synchronizingsignals taken from the tapes by head-2 2 is used lto 'amplitudefmodulate and the other taken from the other tape by head 23 isnsed to phase modulate a common radio carrierwave'of, for example, 25 .megacycles in vtransmitter 24. The two corresponding audio signls, reduced inv frequency because ofthe lower speed of the tapes, are taken-from the tapes by reproducing heads 25 and`26fand arefco'nducted to telephone lines or to a second multiplex radio transmitter not shown, r1 he operation o f the transmitter 24 will be described later 1 n "l "7"!" Figure 'showsl-themethod of feeding one v ideo charinel of transmitter 24 in Figure 2 when dieI program 'is' be either tape 45 or 49, is drivenat normal speed on transcriber 60. The video and synchronizing signals, now having the original frequencies, are taken from' reproducing head 62, and are fed to the television transmitter 63 to modulate the television carrier wave. The accompanyingk audio signals from reproducing head 64, having the original sound frequencies, are alsofed'totrans` mitter 63. The complete television programis then broadcast in the usual way by transmitter 63 andantenna 65; L

The mode of operation of the duplextransmitterlof Figure 2, which represents one form of a multiplex transmission system, is explained by Figures' and 7. 'In

-Figure 6a, Cp is the'vector of a carrier wave whichV is amplitude modulated by modulation signal Mi. If,`for example, M1 consists'of a single frequency, vsuch mod ula` tion gives rise to twoV equal'modulation vectors, M11 and' M111 which rotate in opposite directions with respectto vector Cp with an angular frequency equal tetlie angular frequency of M1.

A second 'modulation signal VMz amplitude modulates a carrier wave Ca equal to carrier wavevCl, but differing'from-Cl,v by 90 in phase. In this case, however, the' carrier C, is suppressed aftermodulation while the modulation" components M21 and M211 are retained. The carrier wave .Cp is then added to M21 and' M21? producingj a phase-modulated wave with a small yamount of ampli-,

tude modulation. The vector sum"wabbles,thro`ugh anl angle` of plus and `.minus @degrees between the limits A1 vandA'z.v vA clipper orlimiter is'ithen'usedtomaintain true phase-modulated carrier. The amplitude-modulated signal of Figure 6a is added to the phase-modulated signal of Figure 6b, and then amplified for radiation by the antenna.

Figure 7 shows in block form the transmitter in Figure 2 comprising elements all individually well known in the art, which when combined as shown produce the two kinds of modulation illustrated in Figure 6. A crystal oscillator 70 feeds a voltage of carrier frequency, and

represented by vector Cp in Figure 6b, to bulfer ampliliers 71 and 72. 'I'he output of amplifier 71 is fed to modulator 73 which also receives modulation signal M1 amplified by amplifier 74. The output of modulator 73 is an amplitude-modulated signal shown in Figure 6a. This signal is increased in power by the radio class B ampliier` 75.

The output of amplifier 72, which corresponds to vector Cp in Figure 6b, is shifted forward or backward in phase by 90 degrees by block 76, giving a voltage corresponding to vector CA in Figure 6b. This voltage is impressed upon the balanced modulator 77 upon which is also impressed the second `modulating signal M2 amplilied by block 78. The balanced modulator 77 suppresses the carrier CA but passes on to block 79 the two side bands represented by vectors M21 and M211 in Figure 6b.

Carrier voltage Cp from amplifier 72 is then added in block 79 to the two side bands supplied by block 77. This approximately phase-modulated signal is amplified in block 80 and then clipped in block 81 to give the true phase-modulated signal shown in Figure 6b. The phasemodulated signal and the amplitude-modulated signal are then combined by adder 82, and the combined signal is` further increased in power by ampliiier 83, and nally radiated by antenna 84.

The receiver, shown in Figure 8, is made up of elements all of which are individually well known in the art. An antenna 90 feeds a radio-frequency amplifier 91. The output of amplifier 91, combined with the output of oscillator 93 'in the rst detector 92, gives a modulated intermediate-frequency wave which is increased by amplier 94.

The variations in amplitude of the output of amplier 94 are detected by the second detector 95, giving the modulated signal M1.

The variations in amplitude of the combined signals from amplifier 94 are clipped off by limiter 96,'leaving only such variations in phase as were produced in the transmitter by modulation M2. The phase-sensitive detector 97 gives the modulation signal M2.

Although only a few of the various forms in which this invention may be embodied have been shown herein, it is to be understood that the invention is not limited to any specific construction but may be embodied in various forms without departing from the spirit of the invention.

What is claimed is: 1. The method of relaying television-type signals over ratio, transmitting simultaneously by two or more channels of a multiplex radio system said last signals on a single carrier wave of a frequency lower than a normal television carrier frequency by approximately said ratio and is adapted to be transmitted over long distances, receiving and recording said signals simultaneously at a remote point to make two or more records corresponding to said iirst records and operating at said lower speed, transcribing said last records at a speed greater than its recording speed by the inverse of said ratio to produce derived signals havingthe original television-signal frequencies, modulating a carrier wave of normal television carrier frequency separately by each of said last signals, and transmitting said last modulated carrier.

2. The method set forth in claim 1 in which said two or more signals comprise separate programs.

3. The method set forth in claim 1 in which the video, synchronizing, and audio signals are recorded on separate tracks of a record and the audio signals are transmitted separately.

4. The method set forth in claim 3 in which the multiplex carrier wave is modulated by both the video signals and the synchronizing signals. v

5. A system for relaying television-type signals over long distances, which comprises means for producing two or more television-type signals each having normal television signal frequencies, means for recording said signals electrically to make two or more records at normal speed carrying said signals at the original television signal frequencies, means for continuously transcribing each of said records at a lower speed to produce signals corresponding to said original signals but having frequencies which have a predetermined ratio to the original fre quencies, means for transmitting simultaneously by a plurality of channels of a multiplex radio system said last signals on a single carrier wave of a frequency lower than a standard television carrier frequency by about said ratio and is adapted to be transmitted over long distances,

long distances, which comprises producing two or more television-type `signals having normal television-signal frequencies, recording said signals electrically to make two or more records operating at normal speed carrying said signals at the original television-signal frequencies, continuously transcribing said records simultaneously at a speed lower than each of said normal speed by a predetermined ratio to produce signals for each record cori responding to said first signals but having frequencies which are lower than the original frequencies by said remote means for receiving simultaneously said transmitted signals, means for recording the received signals to make two or more records at said lower speed, means for transcribing said last records at normal speed to produce signals having the original television signal frequencies, means for modulating a carrier wave of standard television carrier frequency by said last signals, and means for transmitting said last modulated carrier.

6. A system as set forth in claim 5 in which said records are made on magnetic tape.

7. A system as set forth in claim 6 in which the television-type signals include video signals, synchronizing signals, and audio signals, said signals being separated and recorded on separate tracks of said tape.

8. A system as set forth in claim 7 in which said audio signals are transmitted over a separate channel.

References Cited in the tile of this patent UNITED STATES PATENTS `1,677,296 Resenbaum truly 17, 192s 1,735,037 Carpe Nov. 12, 1929 2,170,751V Gabrilovitch Aug. 22, 1939 2,312,835 Hansell Mar. 2, 1943 2,321,611 Moynihan June 15, 1943 2,453,773 Young Nov. 16, 1948 FOREIGN PATENTS 346,456 Great Britain Mar. 30, 19.31 

